Specimens of two different kinds of bake hardening steels (BH-Mn and BH-P) were prepared and treated with different annealing processes (water quenching and overaging). A novel technique of three dimensional atom probe was used to investigate solute distributions in these steels. The results indicate that C concentration decreases, whereas V increases during overaging in both bake hardening steels. The conclusion that no vanadium carbides pre- cipitate during the overaging is therefore originally obtained by microanalysis in bake hardening steels. Moreover, bake hardening values of all the specimens were tested by tensile experiments with 2 0/~ pre-deformation. However, those of overaged specimens were further measured with higher levels of pre-deformation because no bake hardening phenomenon was present at 2% pre-deformation. As the pre-deformation increases from 2% to 6% and 8%, both overaged steels show bake hardening values, and the value data are almost the same.
参考文献
| [1] | Taylor K A;Speer J G.Development of Vanadium-Alloyed, Bake-Hardenable Sheet Steels for Hot-Dip Coated Applications[A].Warrendale:ISSAIME,1997:49. |
| [2] | Girina O;Bhattacharya D.Effect of Vanadium on Mechanical Properties and Bake Hardenability in ULC Steels[A].Baltimore,1999:435. |
| [3] | Waterschoot T;Vandeputte S;De Cooman B C.The Influence of P, Si and Mn on the Mechanical Properties and Bake Hardening of Ti ULC Steels[A].Baltimore,1999:425. |
| [4] | Foley R P;Fine M E;Bhat S K.Bake Hardening Steels: To-ward Improved Formability and Strength[A].Warrendale:ISSAIME,1998:653. |
| [5] | Saitoh H;Ushioda K .Influences of Phosphorus on the Solubility of Carbon in Ferrite and on Snoek Peak[J].Materials Transactions-Japan Institute of Metals,1993,34:13. |
| [6] | WEN Yi-ting;SU Ouan-min;Wuttig M.Interstitial Analysis of Ultra Low Carbon and Interstitial Free Steels[A].Warrenda le:ISS-AIME,1998:271. |
| [7] | De A.K.;Blauwe K.D. .Effect of dislocation density on the low temperature aging behavior of an ultra low carbon bake hardening steel[J].Journal of Alloys and Compounds: An Interdisciplinary Journal of Materials Science and Solid-state Chemistry and Physics,2000(1/2):405-410. |
| [8] | B. Soenen;A. K. De;S. Vandeputte .Competition between grain boundary segregation and Cottrell atmosphere formation during static strain aging in ultra low carbon bake hardening steels[J].Acta materialia,2004(12):3483-3492. |
| [9] | WALEED AL-SHALFAN;JOHN G. SPEER;KIP FINDLEY .Effect of Annealing Time on Solute Carbon in Ultralow-Carbon Ti-V and Ti-Nb Steels[J].Metallurgical and Materials Transactions, A. Physical Metallurgy and Materials Science,2006(1):207-216. |
| [10] | Storozheva L M;Escher K;Bode R et al.Effect of Niobium and Coiling and Annealing Temperatures on the Microstructure,Mechanical Properties,and Bake Hardening of Ultralow-Carbon Steels for the Automotive Industry[J].Metal Science and Heat Treatment,2002,44(03):102. |
| [11] | Vasilyev AA;Lee HC;Kumin NL .Nature of strain aging stages in bake hardening steel for automotive application[J].Materials Science & Engineering, A. Structural Materials: Properties, Misrostructure and Processing,2008(1/2):282-289. |
| [12] | De A K;Vandeputte S;De Cooman B C .Static Strain Aging Behavior of Ultra Low Carbon Bake Hardening Steel[J].Scripta Materialia,1999,41(08):831. |
| [13] | J.Z. ZHAO;A.K. DE;B.C. De COOMAN .Formation of the Cottrell Atmosphere during Strain Aging of Bake-Hardenable Steels[J].Metallurgical and Materials Transactions, A. Physical Metallurgy and Materials Science,2001(2):417-423. |
| [14] | A. K. De;S. Vandeputte;B. C. De Cooman .Kinetics of strain aging in bake hardening ultra low carbon steel-- a comparison with low carbon steel[J].Journal of Materials Engineering and Performance,2001(5):567-575. |
| [15] | Miller M K .Imaging Elusive Solute Atoms[J].Science,1999,286(5448):2285. |
| [16] | A. J. Craven;M. MacKenzie;A. Cerezo .Spectrum imaging and three-dimensional atom probe studies of fine particles in a vanadium micro-alloyed steel[J].Materials Science and Technology,2008(6):641-650. |
| [17] | D. BLAVETTE;P. DUVAL;L. LETELLIER .ATOMIC-SCALE APFIM AND TEM INVESTIGATION OF GRAIN BOUNDARY MICROCHEMISTRY IN ASTROLOY NICKEL BASE SUPERALLOYS[J].Acta materialia,1996(12):4995-5005. |
| [18] | Menand A;Cadel E;Pareige C et al.Three-Dimensional Atomic Scale Microscopy With the Atom Probe[J].Ultramicroscopy,1999,78(1/2/3/4):63. |
| [19] | Hono K .Atom Probe Microanalysis and Nanoscale Microstructures in Metallic Materials[J].Acta Materialia,1999,47(11):3127. |
| [20] | Wilde J.;Cerezo A. .THREE-DIMENSIONAL ATOMIC-SCALE MAPPING OF A COTTRELL ATMOSPHERE AROUND A DISLOCATION IN IRON[J].Scripta materialia,2000(1):39-48. |
| [21] | D.-H. Ping;K. Hono;J.F. Nie .Atom probe characterization of plate-like precipitates in a Mg-RE-Zn-Zr casting alloy[J].Scripta materialia,2003(8):1017-1022. |
| [22] | J.C. OH;T. OHKUBO;T. MUKAI .TEM and 3DAP Characterization of an Age-Hardened Mg-Ca-Zn Alloy[J].Scripta materialia,2005(6):675-679. |
| [23] | Pereloma E V;Timokhina I B;Miller M K et al.Three-Dimensional Atom Probe Analysis of Solute Distribution in Tbermomechanically Processed TRIP Steels[J].Acta Materialia,2007,55(08):2587. |
| [24] | F.G. Caballero;M.K. Miller;C. Garcia-Mateo .Redistribution of alloying elements during tempering of a nanocrystalline steel[J].Acta materialia,2008(2):188-199. |
| [25] | Y. Yamaguchi;J. Takahashi;K. Kawakami .The study of quantitativeness in atom probe analysis of alloying elements in steel[J].Ultramicroscopy,2009(5):541-544. |
| [26] | 王华,史文,何燕霖,符仁钰,李麟.Mn和P在超低碳烘烤硬化钢中的分布形态及其对拉伸行为的影响研究[J].金属学报,2011(03):263-268. |
| [27] | Sylvie Dionne;Elhachmi Essadiqi;Greg McMahon.A Study of Recrystallization and Phosphorus Segregation During Annealing of a Rephosphorized Interstitial Free (IF) Steel[A].Baltimore,1999:235. |
| [28] | Cottrell A H;Bilby B A .Dislocation Theory of Yielding and Strain Ageing of Iron[J].Proceedings of the Physical Society Section A,1949,62:49. |
上一张
下一张
上一张
下一张
计量
- 下载量()
- 访问量()
文章评分
- 您的评分:
-
10%
-
20%
-
30%
-
40%
-
50%